Translational Neuro-Oncology Lab
Kalil Abdullah Lab
University of Pittsburgh
Department of Neurological Surgery
Our Mission
The Translational Neuro-Oncology Lab aims to advance the understanding and treatment of malignant brain tumors by combining novel model systems and unbiased multi-omic approaches to answer pressing clinical questions facing our patients and elucidate mechanisms driving brain tumor development and progression. We utilize novel three-dimensional patient-derived organoids to study key players in the tumor microenvironment and screen therapeutic compounds in a more physiologically relevant model system. We primarily focus on translational targets and biological processes identified and validated in an institutional repository of primary human malignant brain tumor samples. To date, our findings have helped elucidate therapeutic vulnerabilities in malignant brain tumors and informed clinical trials for our patients. Our laboratory benefits from adaptive and collaborative working relationships spanning multiple institutions and our affiliation with the world-renowned Hillman Cancer Center at the University of Pittsburgh.
Selected Publications
-
Establishment of patient-derived organoid models of lower-grade glioma
Neuro Oncol. 2022 Apr 1;24(4):612-623
Historically, creating patient-derived models of lower-grade glioma (LGG) has been challenging, contributing to few experimental platforms that support laboratory-based investigations of this disease. Although organoid modeling approaches have recently been employed to create in vitro models of high-grade glioma (HGG), it is unknown whether this approach can be successfully applied to LGG. In this study, we developed an optimized protocol for the establishment of organoids from LGG primary tissue samples by utilizing physiologic (5%) oxygenation conditions and employed it to produce the first known suite of these models. To assess their fidelity, we surveyed key biological features of patient-derived organoids using metabolic, genomic, histologic, and lineage marker gene expression assays. Organoid models were created with a success rate of 91% (n = 20/22) from primary tumor samples across glioma histological subtypes and tumor grades (WHO Grades 1-4). Patient-derived organoids recapitulated stemness, proliferative, and tumor-stromal composition profiles of their respective parental tumor specimens. Cytoarchitectural, mutational, and metabolic traits of parental tumors were also conserved. Importantly, LGG organoids were maintained in vitro for weeks to months and reanimated after biobanking without loss of integrity. We report an efficient method for producing faithful in vitro models of LGG. New experimental platforms generated through this approach are well positioned to support preclinical studies of this disease, particularly those related to tumor immunology, tumor-stroma interactions, identification of novel drug targets, and personalized assessments of treatment response profiles.
-
De novo pyrimidine synthesis is a targetable vulnerability in IDH mutant glioma
Cancer Cell. 2022 Sep 12;40(9):939-956.e16
Mutations affecting isocitrate dehydrogenase (IDH) enzymes are prevalent in glioma, leukemia, and other cancers. Although mutant IDH inhibitors are effective against leukemia, they seem to be less active in aggressive glioma, underscoring the need for alternative treatment strategies. Through a chemical synthetic lethality screen, we discovered that IDH1-mutant glioma cells are hypersensitive to drugs targeting enzymes in the de novo pyrimidine nucleotide synthesis pathway, including dihydroorotate dehydrogenase (DHODH). We developed a genetically engineered mouse model of mutant IDH1-driven astrocytoma and used it and multiple patient-derived models to show that the brain-penetrant DHODH inhibitor BAY 2402234 displays monotherapy efficacy against IDH-mutant gliomas. Mechanistically, this reflects an obligate dependence of glioma cells on the de novo pyrimidine synthesis pathway and mutant IDH's ability to sensitize to DNA damage upon nucleotide pool imbalance. Our work outlines a tumor-selective, biomarker-guided therapeutic strategy that is poised for clinical translation.
-
Semi-Automated Computational Assessment of Cancer Organoid Viability Using Rapid Live-Cell Microscopy
Cancer Inform. 2022 May 26;21:11769351221100754
The creation of patient-derived cancer organoids represents a key advance in preclinical modeling and has recently been applied to a variety of human solid tumor types. However, conventional methods used to assess in vivo tumor tissue treatment response are poorly suited for the evaluation of cancer organoids because they are time-intensive and involve tissue destruction. To address this issue, we established a suite of 3-dimensional patient-derived glioma organoids, treated them with chemoradiotherapy, stained organoids with non-toxic cell dyes, and imaged them using a rapid laser scanning confocal microscopy method termed "Apex Imaging." We then developed and tested a fragmentation algorithm to quantify heterogeneity in the topography of the organoids as a potential surrogate marker of viability. This algorithm, SSDquant, provides a 3-dimensional visual representation of the organoid surface and a numerical measurement of the sum-squared distance (SSD) from the derived mass center of the organoid. We tested whether SSD scores correlate with traditional immunohistochemistry-derived cell viability markers (cellularity and cleaved caspase 3 expression) and observed statistically significant associations between them using linear regression analysis. Our work describes a quantitative, non-invasive approach for the serial measurement of patient-derived cancer organoid viability, thus opening new avenues for the application of these models to studies of cancer biology and therapy.
-
Selective and brain-penetrant lanosterol synthase inhibitors target glioma stem-like cells by inducing 24(S),25-epoxycholesterol production
Cell Chem Biol. 2023 Feb 16;30(2):214-229.e18
Glioblastoma (GBM) is an aggressive adult brain cancer with few treatment options due in part to the challenges of identifying brain-penetrant drugs. Here, we investigated the mechanism of MM0299, a tetracyclic dicarboximide with anti-glioblastoma activity. MM0299 inhibits lanosterol synthase (LSS) and diverts sterol flux away from cholesterol into a "shunt" pathway that culminates in 24(S),25-epoxycholesterol (EPC). EPC synthesis following MM0299 treatment is both necessary and sufficient to block the growth of mouse and human glioma stem-like cells by depleting cellular cholesterol. MM0299 exhibits superior selectivity for LSS over other sterol biosynthetic enzymes. Critical for its application in the brain, we report an MM0299 derivative that is orally bioavailable, brain-penetrant, and induces the production of EPC in orthotopic GBM tumors but not normal mouse brain. These studies have implications for the development of an LSS inhibitor to treat GBM or other neurologic indications.
-
A Modified Nucleoside 6-Thio-2′-Deoxyguanosine Exhibits Antitumor Activity in Gliomas
Clin Cancer Res. 2021 Dec 15;27(24):6800-6814
To investigate the therapeutic role of a novel telomere-directed inhibitor, 6-thio-2′-deoxyguanosine (THIO) in gliomas both in vitro and in vivo. A panel of human and mouse glioma cell lines was used to test therapeutic efficacy of THIO using cell viability assays, flow cytometric analyses, and immunofluorescence. Integrated analyses of RNA sequencing and reverse-phase protein array data revealed the potential antitumor mechanisms of THIO. Four patient-derived xenografts (PDX), two patient-derived organoids (PDO), and two xenografts of human glioma cell lines were used to further investigate the therapeutic efficacy of THIO. THIO was effective in the majority of human and mouse glioma cell lines with no obvious toxicity against normal astrocytes. THIO as a monotherapy demonstrated efficacy in three glioma cell lines that had acquired resistance to temozolomide. In addition, THIO showed efficacy in four human glioma cell lines grown as neurospheres by inducing apoptotic cell death. Mechanistically, THIO induced telomeric DNA damage not only in glioma cell lines but also in PDX tumor specimens. Integrated computational analyses of transcriptomic and proteomic data indicated that THIO significantly inhibited cell invasion, stem cell, and proliferation pathways while triggering DNA damage and apoptosis. Importantly, THIO significantly decreased tumor proliferation in two PDO models and reduced the tumor size of a glioblastoma xenograft and a PDX model. The current study established the therapeutic role of THIO in primary and recurrent gliomas and revealed the acute induction of telomeric DNA damage as a primary antitumor mechanism of THIO in gliomas.
-
Antitumor Activity of a Mitochondrial-Targeted HSP90 Inhibitor in Gliomas
Clin Cancer Res. 2022 May 13;28(10):2180-2195
To investigate the antitumor activity of a mitochondrial-localized HSP90 inhibitor, Gamitrinib, in multiple glioma models, and to elucidate the antitumor mechanisms of Gamitrinib in gliomas. A broad panel of primary and temozolomide (TMZ)-resistant human glioma cell lines were screened by cell viability assays, flow cytometry, and crystal violet assays to investigate the therapeutic efficacy of Gamitrinib. Seahorse assays were used to measure the mitochondrial respiration of glioma cells. Integrated analyses of RNA sequencing (RNAseq) and reverse phase protein array (RPPA) data were performed to reveal the potential antitumor mechanisms of Gamitrinib. Neurospheres, patient-derived organoids (PDO), cell line-derived xenografts (CDX), and patient-derived xenografts (PDX) models were generated to further evaluate the therapeutic efficacy of Gamitrinib. Gamitrinib inhibited cell proliferation and induced cell apoptosis and death in 17 primary glioma cell lines, 6 TMZ-resistant glioma cell lines, 4 neurospheres, and 3 PDOs. Importantly, Gamitrinib significantly delayed the tumor growth and improved survival of mice in both CDX and PDX models in which tumors were either subcutaneously or intracranially implanted. Integrated computational analyses of RNAseq and RPPA data revealed that Gamitrinib exhibited its antitumor activity via (i) suppressing mitochondrial biogenesis, OXPHOS, and cell-cycle progression and (ii) activating the energy-sensing AMP-activated kinase, DNA damage, and stress response. These preclinical findings established the therapeutic role of Gamitrinib in gliomas and revealed the inhibition of mitochondrial biogenesis and tumor bioenergetics as the primary antitumor mechanisms in gliomas.
-
Mismatch repair protein mutations in isocitrate dehydrogenase (IDH)-mutant astrocytoma and IDH-wild-type glioblastoma
Neurooncol Adv. 2023 Jul 12;5(1):vdad085
Mutations in mismatch repair (MMR) genes (MSH2, MSH6, MLH1, and PMS2) are associated with microsatellite instability and a hypermutator phenotype in numerous systemic cancers, and germline MMR mutations have been implicated in multi-organ tumor syndromes. In gliomas, MMR mutations can function as an adaptive response to alkylating chemotherapy, although there are well-documented cases of germline and sporadic mutations, with detrimental effects on patient survival. By comparing the clinical, pathologic, and molecular features of IDH-mutant astrocytomas and IDH-wild-type glioblastomas with MMR mutations to tumors without MMR mutations, and those that developed MMR mutations between initial presentation and recurrence, we found that in both IDH-mutant astrocytoma and IDH-wild-type glioblastoma cohorts, the presence of MMR mutation in primary tumors was associated with significantly higher tumor mutation burden (TMB) (P < .0001); however, MMR mutations only resulted in worse overall survival in the IDH-mutant astrocytomas (P = .0069). In addition, gain of MMR mutation between the primary and recurrent surgical specimen occurred more frequently with temozolomide therapy (P = .0073), and resulted in a substantial increase in TMB (P < .0001), higher grade (P = .0119), and worse post-recurrence survival (P = .0022) in the IDH-mutant astrocytoma cohort. These results suggest that whether present initially or in response to therapy, MMR mutations significantly affect TMB but appear to only influence the clinical outcome in IDH-mutant astrocytoma subsets.
Kalil G. Abdullah, MD, MSc, FAANS
Kalil G. Abdullah is a neurosurgeon specializing in the treatment of adult brain tumors and is the director of translational neuro-oncology at the UPMC Hillman Cancer Center. Dr. Abdullah treats brain tumors using microsurgery techniques and awake craniotomies to map intricate regions of the brain during surgery. He also uses endoscopic and tubular approaches, intraoperative fluorescence, and laser therapy to provide minimally invasive surgery options to his patients.
Our laboratory is focused on developing novel clinical models of glioma and identifying druggable targets to facilitate early-phase clinical trials. Gliomas are intensely heterogeneous tumors that not only contain numerous cell types but also demonstrate the ability to transition between different phenotypic states. This complexity has made developing model systems that recapitulate human tumor biology both difficult and essential. Traditionally, models of gliomas are two-dimensional cell lines and only represent certain subtypes of the highest-grade glioma, glioblastoma. This is because the unique biology of lower-grade gliomas has prevented them from being studied either outside of the lab or in animals. We have created ex-vivo culture systems that allow us to investigate critical aspects of the tumor microenvironment, immune response, and discover targets for therapy. Our laboratory has previously shown the ability to establish lower-grade glioma organoids in vitro, maintain those cultures for extended periods of time, hibernate, and then reanimate tumor tissue without loss of either genetic or phenotypic fidelity. Our work also includes extensive and sophisticated live-cell imaging analysis that allows for longitudinal, non-invasive assessment of organoid response to treatment. Our organoid model systems, in addition to glioma stem cell and mouse models, allow us to perform highly sophisticated assessments of drug response across platforms and identify rare but critical druggable targets in gliomas. These analyses include complex metabolic tracing and immune cell response assessment. Despite the fundamental principles of genomics, immunology, and cellular cancer biology that underlie our work, our group focuses on projects that have a high potential for immediate clinical translation.
Dr. Abdullah earned his medical degree at the Cleveland Clinic Lerner College of Medicine, where he was a National Institutes of Health Howard Hughes Medical Institute Scholar. He completed a residency in neurological surgery at the University of Pennsylvania and then received advanced training in open and endoscopic neurosurgical oncology through a fellowship at the Wellington Hospital in New Zealand. He completed an additional postdoctoral research fellowship in stem cell biology at the University of Pennsylvania and holds a master’s degree from the London School of Economics.
Meet the Team
-
Skyler Oken, BS
Research Specialist
Skyler is a researcher who joined our lab after completing her undergraduate in Biology from Penn State University. She is currently in the process of applying to medical school. Outside of the lab, she enjoys listening to music, playing and watching sports, and spending time with friends and family.
-
Harrison Hicks, BS
Medical Student
Harrison is a medical student at UT Southwestern Medical School interested in neurosurgery and neuro-oncology. He completed his undergraduate in Neuroscience from the University of Texas at Dallas. He enjoys golfing, skiing, and college football.
-
Jeffrey Traylor, MD
Resident Physician
Jeff is a neurosurgery resident at UT Southwestern Medical Center who will be using his dedicated research time to explore genetic, transcriptional, and metabolic features of malignant gliomas. He is an avid guitarist and enjoys skiing, running, and reading.
-
Lilly Tang, BA
Medical Student
Lilly is a medical student in the Physician Scientist Training Program at the University of Pittsburgh Medical School. Her primary research foci are in neuroscience and neurosurgery. She enjoys playing volleyball, exploring the food scene, and hanging out with her cat, May.
-
Namya Manoj, MSc
Research Coordinator
Namya holds a Master’s in Genetics, Genomics, and Bioinformatics from the State University of New York at Buffalo. Her research focuses on understanding brain tumor integration and progression using advanced organoid models. Outside of the lab, Namya enjoys reading, painting, and playing lawn tennis.
-
Kenji Miki, MD, PhD
Post Doctoral Fellow
Kenji is a neurosurgeon from Japan who has joined the lab as a postdoc. His research focuses on brain tumor metabolism and mitochondria. He completed his M.D. and Ph.D. at Kyushu University. His hobbies include playing the piano and enjoying good food.
Lab Alumni
Cylania Bird
Position: Medical Student (2019 - 2021)
Subsequent Position: Neurosurgery Resident Physician at University of Michigan
Joesph Buehler
Position: Research Specialist (2018 - 2021)
Subsequent Position: Graduate Student at Emory University
Mohamad El Shami
Position: Post-Doctoral Associate (2021 - 2023)
Subsequent Position: Internal Medicine Resident at Michigan State University-Grand Rapids
Jenna Thomas
Position: Clinical Research Coordinator (2019 - 2021)
Subsequent Position: Medical Student at the University of Texas Houston McGovern Medical School
Lauren Gattie
Position: Clinical Research Coordinator (2021 - 2020)
Subsequent Position: Medical Student at the University of Tennessee Health Science Center
Support Our Research
A gift to the Abdullah Lab will support our research on brain tumors.
If you would like to make a donation, please contact:
Justin R. Meyer
Medical and Health Sciences Foundation
Phone: (412) 578–9273
Email: mjustin@pmhsf.org
Interesting in joining our lab?
We are looking for highly motivated students, postdoctoral scientists, and senior scientists to help accelerate our advancement of novel preclinical models of malignant brain tumors to comprehensively profile the landscape of malignant brain tumors, with the ultimate goal of developing novel therapeutics to help our future patients. A competitive applicant for this position will have a significant interest in malignant brain tumors, cancer metabolism, and/or bioinformatics. Candidates must hold, at minimum, a B.S./B.A., Ph.D., or M.D. from an accredited institution in a relevant field. Prospective students will be evaluated on a case-by-case basis. Candidates must have a strong work ethic, analytical, communication, and organizational skills, the ability to work independently, and a determination to advance the field.
If interested, please submit a CV and brief outline of your research interests and career goals to Kalil G. Abdullah (abdullahkg@upmc.edu).
Contact Us
University of Pittsburgh Department of Neurological Surgery
200 Lothrop Street, Suite B-400
Pittsburgh, PA 15213
Phone: (412) 647-3685
Neurosurgery Clinic - UPMC Hillman Cancer Center
5115 Centre Avenue
Pittsburgh, PA 15232
Phone: (412) 647-7614